CN203775182U - RS232 and infrared communication interface switching circuit capable of automatically taking power - Google Patents

Abstract

The utility model relates to an RS232 and infrared communication interface switching circuit capable of automatically taking power, which is used for realizing switching between a wired communication RS232 interface and a wireless communication infrared interface. The circuit is characterized by comprising a rectifying circuit, a voltage doubling circuit, a voltage stabilizer, a 38kHz oscillating circuit, an infrared transmitting circuit, an infrared receiving circuit and a receiving level switching circuit, wherein the rectifying circuit, the voltage doubling circuit and the voltage stabilizer directly take power from transmit data (TXD) signals and data terminal ready (DTR) indicating signals of an RS232 interface, thereby providing power for the device; the TXD signals controls infrared emission directly; the receiving level switching circuit is adopted to switch intermediate signals outputted by the infrared receiving circuit into receive data (RXD) signals conforming to RS232 standards. The circuit provided by the utility model is simple in structure, does not need an external power supply, and does not need an RS232 and TTL level switching chip.

Description

RS232 and infrared communication interface conversion circuit capable of automatically taking electricity

Technical Field

The utility model relates to a RS232 and infrared communication interface conversion circuit of self-powered belongs to communication interface technical field.

Background

RS232 is a serial physical interface standard and an electrical standard established by the american Electronic Industries Association (EIA), and is currently widely used in serial communication links between systems, and is one of the most widely used serial interfaces in PC and industrial communications. The infrared communication mode adopts infrared light sensation to realize serial signal transmission, can realize low-cost and short-distance wireless data transmission, and is widely applied to various remote control products. In practical application, the conversion of the two communication interfaces is often required to be realized, and the conversion access requirements of wired communication and wireless communication modes are met. In journal of modern electronic technology of 20 th year in 2013, an article "a 232 to infrared circuit design" proposes an RS232 and infrared communication interface conversion circuit, a schematic circuit diagram of which is shown in fig. 1, and a structural diagram of which is shown in fig. 2. In this circuit scheme, there are two disadvantages. The first disadvantage is that the input power Vcc needs to be provided separately for the whole circuit, and the external power requirement will increase the application complexity. The second disadvantage is that the existing conversion circuit needs to realize the conversion between the RS232 level and the TTL level based on RS232 and TTL level conversion chips, then the TTL drives the infrared transmitting circuit and is connected with the infrared receiving circuit. The TTL level is used as an intermediate signal, a conversion chip is added, and complexity and cost are increased.

Disclosure of Invention

The utility model aims at providing a RS232 and infrared communication interface converting circuit from getting electricity directly gets the electricity from RS232 interface signal, needn't need the external power source to insert. Meanwhile, an RS232 and TTL level conversion chip is omitted, and the circuit structure is simplified.

The utility model provides a pair of RS232 and infrared communication interface converting circuit from power takeoff, its characterized in that, this circuit includes: the device comprises a rectifying circuit, a voltage doubling circuit, a voltage stabilizer, a 38kHz oscillating circuit, an infrared transmitting circuit, an infrared receiving circuit and a receiving level conversion circuit; wherein,

the input end of the circuit is connected with a ground signal GND and a transmitting data signal TXD of the RS232 interface, and negative voltage-V is output after rectification;

the voltage doubling circuit converts the input negative voltage-V into positive voltage + V to be output;

the voltage stabilizer converts the input positive voltage + V into power supply voltage VCC required by the work of the 38kHz oscillating circuit, the infrared transmitting circuit and the infrared receiving circuit;

the 38kHz oscillating circuit is connected to a power supply voltage VCC and then outputs a 38kHz modulation square wave;

the infrared transmitting circuit is connected with a power supply voltage VCC, and outputs an infrared transmitting signal modulated by 38kHz when an input transmitting data signal TXD of an RS232 interface is at a high level;

the infrared receiving circuit is connected with a power supply voltage VCC, receives an infrared input signal and outputs an intermediate signal R1;

and the receiving level conversion circuit converts the input intermediate signal R1 into a receiving data signal RXD which accords with the RS232 interface level standard after the positive voltage + V and the negative voltage-V are connected.

Furthermore, the negative voltage-V output by the rectifying circuit, the voltage + V output by the voltage doubling circuit and the voltage VCC output by the voltage stabilizer are connected with a capacitor for filtering and storing energy in parallel relative to a ground signal GND.

Furthermore, the input end of the rectifying circuit is connected with a ground signal GND of the RS232 interface and a data terminal preparation indicating signal DTR.

Further, the rectifier circuit has a second output of positive voltage rectification and is connected to a positive voltage + V.

The utility model discloses a from RS232 of power consumption and infrared communication interface converting circuit's theory of operation is, according to the RS232 interface send data signal TXD and data terminal when no data transmission prepare the characteristic that instruction signal DTR keeps the negative voltage, obtain negative voltage-V through rectifier circuit. The voltage doubling circuit doubles the voltage difference between the ground signal GND and the negative voltage-V by taking the negative voltage-V as a reference, namely, outputs a voltage which is 2V higher than the negative voltage-V, and then obtains a positive voltage + V. The voltage stabilizer converts the positive voltage + V into a power supply voltage VCC relative to a ground signal GND and supplies power to the 38kHz oscillating circuit, the infrared transmitting circuit and the infrared receiving circuit. If the transmit data signal TXD and the data terminal ready indication signal DTR output a positive voltage, a positive voltage + V may also be connected through a rectifying circuit to charge it. From this, rectifier circuit, voltage doubling circuit and stabiliser have constituted the utility model discloses conversion circuit's electrical power generating system gets the electricity from the RS232 interface, need not external power source. And simultaneously, the utility model discloses the circuit directly realizes that RS 232's transmission data signal TXD controls the infrared signal of 38kHz modulation to infrared emission circuit's transmission when TXD is the positive voltage time control infrared interface transmission. The circuit is based on a receiving level conversion circuit, and converts an intermediate signal R1 output by an infrared receiving circuit from 0 to VCC level into + V and-V levels which accord with the input level and logic of an RS232 receiving data signal RXD.

Drawings

Fig. 1 is a schematic diagram of a conventional RS232 and infrared communication interface conversion circuit.

Fig. 2 is a structural diagram of a conventional RS232 and infrared communication interface conversion circuit.

Fig. 3 is a structural diagram of the self-powered RS232 and infrared communication interface conversion circuit of the present invention.

Fig. 4 is a schematic diagram of the self-powered RS232 and infrared communication interface conversion circuit of the present invention.

Detailed Description

The structure diagram of an embodiment of the present invention is shown in fig. 3, and the schematic circuit diagram is shown in fig. 4. The utility model discloses circuit includes rectifier circuit, voltage doubling circuit, stabiliser, 38kHz oscillating circuit, infrared transmitting circuit, infrared receiving circuit and receipt level conversion circuit. The rectification circuit adopts double diodes to send a data signal TXD and a data terminal preparation indicating signal DTR, and negative voltage-V is output after rectification. A voltage doubling circuit is realized by adopting a switched capacitor voltage converter HT7660, the voltage difference between a ground signal GND and a negative voltage-V is doubled, and a voltage which is 2V higher than the negative voltage-V is output, so that a positive voltage + V is obtained. In addition, the rectifier circuit can also be charged directly to the positive voltage + V when the transmit data signal TXD and the data terminal preparation indicator signal DTR are positive. The voltage stabilizer is realized by adopting an LDO voltage conversion chip SPX3819-3.3, and converts positive voltage + V into power supply voltage +3.3V required by the work of the 38kHz oscillating circuit, the infrared transmitting circuit and the infrared receiving circuit. The rectifying circuit outputs negative voltage-V, the voltage doubling circuit outputs voltage + V and the voltage stabilizer outputs voltage VCC, and the voltage doubling circuit is connected with a capacitor for filtering and storing energy in parallel relative to a ground signal GND.

The utility model discloses 38kHz oscillating circuit constitutes based on the six NOT gate chips of 74VHC04 of 38kHz crystal and 3.3V work. Two small capacitors are connected in parallel at two ends of the crystal oscillator to assist the crystal oscillator to start oscillation. And an output waveform signal of the crystal oscillator is connected to the NOT gate circuit, and finally, a modulation square wave with the duty ratio of 50% and the frequency of 38kHz is output. When the transmitting data signal TXD of the infrared transmitting circuit is positive voltage and the 38kHz modulation square wave is high level, the triode is conducted, and the infrared transmitting tube is driven to transmit; when the transmitting data signal TXD is negative voltage or the 38kHz modulation square wave is low level, the triode is not conducted, and the infrared transmitting tube does not transmit. And the light emitting diode connected with the infrared emission tube in series is used as an infrared emission indicator lamp.

The utility model discloses infrared receiving circuit adopts HS0038 as infrared receiving device, realizes receiving level conversion circuit through a not door, an NPN triode and a PNP triode. When receiving an infrared signal, the infrared receiving head HS0038 outputs a low level of 0V, and outputs a positive RXD voltage + V to the RS232 interface through the receiving level conversion circuit. When the infrared signal is not received, the infrared receiving head HS0038 outputs a high level, and the high level is output to the RXD negative voltage-V of the RS232 interface through the receiving level conversion circuit.

The embodiment of the utility model provides a circuit structure is simple, and is with low costs, need not external power source, need not RS232 and TTL level conversion chip.

Claims (4)

1. The utility model provides a RS232 and infrared communication interface converting circuit of self-service electricity, its characterized in that, this circuit includes: the device comprises a rectifying circuit, a voltage doubling circuit, a voltage stabilizer, a 38kHz oscillating circuit, an infrared transmitting circuit, an infrared receiving circuit and a receiving level conversion circuit; wherein,

the input end of the circuit is connected with a ground signal GND and a transmitting data signal TXD of the RS232 interface, and negative voltage-V is output after rectification;

the voltage doubling circuit converts the input negative voltage-V into positive voltage + V to be output;

the voltage stabilizer converts the input positive voltage + V into power supply voltage VCC required by the work of the 38kHz oscillating circuit, the infrared transmitting circuit and the infrared receiving circuit;

the 38kHz oscillating circuit is connected to a power supply voltage VCC and then outputs a 38kHz modulation square wave;

the infrared transmitting circuit is connected with a power supply voltage VCC, and outputs an infrared transmitting signal modulated by 38kHz when an input transmitting data signal TXD of an RS232 interface is at a high level;

the infrared receiving circuit is connected with a power supply voltage VCC, receives an infrared input signal and outputs an intermediate signal R1;

and the receiving level conversion circuit converts the input intermediate signal R1 into a receiving data signal RXD which accords with the RS232 interface level standard after the positive voltage + V and the negative voltage-V are connected.

2. The self-powered RS232 and infrared communication interface conversion circuit as claimed in claim 1, wherein the negative voltage-V output by the rectification circuit, the voltage + V output by the voltage doubling circuit and the voltage VCC output by the voltage regulator are connected in parallel with a capacitor for filtering and storing energy with respect to ground GND.

3. The conversion circuit of the RS232 and infrared communication interface capable of automatically taking electricity as claimed in claim 1, wherein the input end of the rectification circuit is connected with a ground signal GND of the RS232 interface and a data terminal preparation indication signal DTR.

4. The self-powered RS232 and IR communication interface conversion circuit according to claim 1, wherein the rectifier circuit has a second output with positive voltage rectification and is connected to positive voltage + V.